Österreichische Agentur für Gesundheit und Ernährungssicherheit GmbHwww.ages.at
Rapid method for determination of polonium
isotopes in biological matter
Merita Sinojmeri, Claudia Landstetter, Christian Katzlberger, Arno Achatz
Radiation Protection Department
Austrian Agency for Health and Food Safety
IRPA XIII, Glasgow
14.05.2012
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Project description
Polonium isotopes
Analysis review
Method and validation
Results and discussions
Topics
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Project
Radioactivity in wild living fish (2010-2011)
Funded by Austrian Ministry of Health
Scope
Determination of radionuclides concentration inwild fresh water living fish
Ingestion dose calculation of manmade and naturalradionuclides in human
Which radionuclides contribute the most intoingestion dose?
Are there geographical differences?
Radionuclide concentration depending on the fishtype
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Polonium isotopes
•28 radioactive isotopes (Z=84, A = 192-218)
• 235U, 238U, 232Th decay chain
• 210Po ca. 100 µg per ton Uranium ore
• 210Po comes in the atmosphere through 222Rn (238U)
• 210Po specific activity 166 TBq g-1
•Chemical valence -2, +2, +4 and +6
•Complex formation
•Volatility
• 210Po (138 d, alpha 5,3 MeV)
• 209Po (113y, alpha 4,9 MeV)4
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Review of polonium analysis
Two main methods
Extractive organic material & Liquid Scintillation Counting
Spontaneous deposition & Alpha spectrometry
Advantages
Liquid Scintillation CountingEasy
Simultaneously 210Po, 210Pb, 210Bi
Alpha-SpectrometryEasyNo interferencesNo need to extract or separate PoloniumNo need to wait for equilibrium
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Disadvantages
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Liquid Scintillation Counting
Total chemical recovery is assumed
Same self absorption
Same extraction yield
Same Polonium volatility
Alpha-Beta crosstalk correction
Other interferences
Alpha-Spectrometry210
Pb can not be simultaneously measured with 210
Po
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Methode
Tracer 209Po addition
Total digestion
Auto deposition
Isotope dilution
alpha-spectrometry
MDA≤0,1 mBq
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Methode validation
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Ascorbic acid and pH set influence on the self deposition of Polonium
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10
20
30
40
50
60
70
80
90
100
0,00 50,00 100,00 150,00 200,00 250,00 300,00 350,00 400,00 450,00
Time/min
%
Po % Asc.0%
Pb, Bi Asc.0%
Po % 0,5MHCl
PbBi 0,5MHCl
Po Asc.+ pH=2
Bi, Pb +Asc+pH=2
Fig.1. Influence of ascorbic acid and pH set during
the self-deposition of Polonium, Lead and Bismuth
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Method validation
Time interval correction
Reference time
Equilibrium (210Pb, 210Bi) *prompt analysis
Separation time
Measurement time
Interferences (210Pb, 210Bi)
Reference materials
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Referencematerial
Matrix type Information ActivityBq kg-1
LaboratoryActivityBq kg-1
IAEA-414 Fish 1,8-2,5 (11) 1,9 ± 0,2 (5)
IAEA-385 Sea sediment 31,2-35,3(16) 32,4 ± 1,9 (2)
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Sampling location
Zeller
Grundl & Toplitz Neusiedel
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Results and discussion
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Fig. 2 Median values of the concentration of 210Po in different type
of fish in the Grundl, Zeller, Toplitz and Neusiedl lakes in Austria
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Discussion
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Fig. 3 210Po Activity concentration in northern pike in
Grundl lake variation with fish weight
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Results and discussion
COUNCIL DIRECTIVE 96/29/EURATOM of 13 May 1996laying down basic safety standards for the protection of thehealth of workers and the general public against the dangersarising from ionizing radiation
Annex III, Table A. Ingestion dose coefficients for membersof the public
Freshwater wild fish consumption in Austria is ca. 0,5 kg/year (*2010)
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Group Conversion factor
Ingestion dose
Children≤1a 26 µSv Bq-1 58 µSv year-1
Adults>17a 1,2 µSv Bq-1 2,7 µSv year-1
Worst case(0,5 kg/week)
26 µSv Bq-1 4 mSv year-1
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Thank you for your attention
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